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A Survey of Spectrum Sensing Algorithm for Cognitive Radio Applications

A Survey of Spectrum Sensing Algorithm for Cognitive Radio Applications. YaGun Wu netlab. Outline. Introduction Challenges Spectrum Sensing Methods Cooperative Sensing Spectrum Sensing in Current Wireless Standards Conclusion. Introduction.

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A Survey of Spectrum Sensing Algorithm for Cognitive Radio Applications

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  1. A Survey of Spectrum Sensing Algorithm for Cognitive Radio Applications YaGun Wu netlab

  2. Outline • Introduction • Challenges • Spectrum Sensing Methods • Cooperative Sensing • Spectrum Sensing in Current Wireless Standards • Conclusion

  3. Introduction • Cognitive radio: A radio that can change its transmitter parameters based on interaction with the environment in which it operates.

  4. Spectrum Holes • Main aspect: One main aspect of cognitive radio is related to autonomously exploiting locally unused spectrum to provide new paths to spectrum access. Power Frequency Spectrum in use by Primary user SpectrumHole Time

  5. Function on Cognitive radio • Functions • Spectrum sensing • Spectrum management • Spectrum sharing • Spectrum mobility • Cognitive Cycle • Spectrum sensing • Spectrum analysis • Spectrum decision

  6. Several Aspects

  7. Multi-Dimensional Spectrum Awareness • Conventional sensing methods usually exploits three dimensions: frequency, time, and space. • Multi-dimensional spectrum awareness: include the process of identifying occupancy in all dimensions of the spectrum space and finding spectrum holes, or more precisely spectrum space holes.

  8. Multi-Dimensional Spectrum Awareness

  9. Multi-Dimensional Spectrum Awareness

  10. Challenges • Hardware requirements • Hidden primary user problem • Detecting spread spectrum primary users • Sensing duration and frequency • Decision fusion in cooperative sensing

  11. Single-Radio and Dual-Radio • Two different architectures of sensing single-radio: only a specific time slot is allocated for spectrum sensing. dual-radio: one radio chain is dedicated for data transmission and reception while the other chain is dedicated for spectrum monitoring

  12. Challenges • Hidden primary user problem: many factors including severe multipath fading or shadowing observed by secondary users while scanning for primary users’ transmissions. • Detecting spread spectrum primary users: The two major spread spectrum technologies are frequency hoping spread-spectrum (FHSS) and direct-sequence spread spectrum (DSSS).

  13. Challenges • Sensing duration and frequency: In order to prevent interference to and from primary license owners, cognitive radio should be able to identify the presence of primary users as quickly as possible. • Decision fusion in cooperative sensing: • Security:

  14. Spectrum Sensing Methods • Energy Detector Based Sensing: The signal is detected by comparing the output of the energy detector with a threshold which depends on the noise floor. • Inability to differentiate interference from primary users and noise, and poor performance under low signal-to-noise ratio (SNR)values.

  15. Spectrum Sensing Methods • Waveform-Based Sensing: Known patterns are usually utilized in wireless systems to assist synchronization or for other purposes. Such patterns include preambles, midambles, regularly transmitted pilot patterns, spreading sequences etc. • Waveform-based sensing requires short measurement time.

  16. Spectrum Sensing Methods • Cyclostationarity-Based Sensing: Cyclostationarity feature detection is a method for detecting primary user transmissions by exploiting the cyclostationarity features of the received signals. • The cyclostationarity based detection algorithms can differentiate noise from primary users’ signals.

  17. Spectrum Sensing Methods • Radio Identification Based Sensing: • Matched-Filtering: Matched-filtering is known as the optimum method for detection of primary users when the transmitted signal is known. It requires perfect knowledge of the primary users signaling features. • Other Sensing Methods:

  18. Comparison of Various Sensing Methods • Waveform-based sensing is more robust than energy detector and cyclostationarity based methods. • Energy detector based sensing is limited. • Cyclostationary-based methods perform worse than energy detector based sensing methods when the noise is stationary.

  19. Cooperative Sensing • Cooperative sensing decreases the probabilities of mis-detection and false alarm considerably. It can solve hidden primary user problem and it can decrease sensing time. • Using control channel to share spectrum sensing result. • Collaborative spectrum sensing is most effective when collaborating cognitive radios observe independent fading or shadowing.

  20. Centralized ,DistributedSensing and External Sensing Centralized Sensing • In centralized sensing, a central unit collects sensing information from cognitive devices, identifies the available spectrum, and broadcasts this information to other cognitive radios or directly controls the cognitive radio traffic. • Only the cognitive radios with reliable information are allowed to report their decisions to the central unit.

  21. Centralized ,DistributedSensing and External Sensing Distributed Sensing • In the case of distributed sensing, cognitive nodes share information among each other but they make their own decisions as to which part of the spectrum they can use. • Only final decisions are shared in order to minimize the network overhead due to collaboration. External Sensing • An external agent performs the sensing and broadcasts the channel occupancy information to cognitive radios.

  22. Spectrum Sensing in Current Wireless Standards • IEEE 802.11k: It is a standard for radio resource management. Some of the measurements include channel load report, noise histogram report and station statistic report. • Bluetooth: Adaptive frequency hopping (AFH), is introduced to the Bluetooth standard to reduce interference between wireless technologies sharing the 2.4GHz unlicensed radio spectrum.

  23. Spectrum Sensing in Current Wireless Standards • IEEE 802.22: It based wireless regional area network (WRAN) devices sense TV channels and identify transmission opportunities. • It is a practical example of centralized collaborative sensing.

  24. Conclusion • Spectrum is a very valuable resource in wireless communication systems. • Cognitive radio is one of the efforts to utilize the available spectrum more efficiently through opportunistic spectrum usage. • One of the important elements of cognitive radio is sensing the available spectrum opportunities.

  25. Thank you!!

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